def config(self, config):
self.ax.set_autoscale_on(False)
chart = config.getboolean("Psychr", "chart")
xlabel = "Tdb, " + Temperature.text()
ylabel = "%s, %s/%s" % (
QtWidgets.QApplication.translate("pychemqt", "Absolute humidity"),
Mass.text(), Mass.text())
tmin = Temperature(config.getfloat("Psychr", "isotdbStart")).config()
tmax = Temperature(config.getfloat("Psychr", "isotdbEnd")).config()
wmin = config.getfloat("Psychr", "isowStart")
wmax = config.getfloat("Psychr", "isowEnd")
if chart:
self.ax.set_xlabel(xlabel, size="large")
self.ax.set_ylabel(ylabel, size="large")
self.ax.set_xlim(tmin, tmax)
self.ax.set_ylim(wmin, wmax)
self.ax.yaxis.set_ticks_position("right")
self.ax.yaxis.set_label_position("right")
self.ax.figure.subplots_adjust(left=0.05, top=0.95)
else:
self.ax.set_xlabel(ylabel, size="large")
self.ax.set_ylabel(xlabel, size="large")
self.ax.set_xlim(wmin, wmax)
self.ax.set_ylim(tmin, tmax)
self.ax.xaxis.set_ticks_position("top")
self.ax.xaxis.set_label_position("top")
self.ax.figure.subplots_adjust(right=0.95, bottom=0.05)
kw = formatLine(config, "Psychr", "crux")
self.lx = self.ax.axhline(**kw) # the horiz line
self.ly = self.ax.axvline(**kw) # the vert line
def curveIndexChanged(self, index):
"""Show the composition unit appropiated to the new curve selected"""
if index == 3:
header = ["wt.%", "Tb, " + Temperature.text()]
else:
header = ["Vol.%", "Tb, " + Temperature.text()]
self.curvaDestilacion.tabla.setHorizontalHeaderLabels(header)
def config(self, config):
self.ax.set_autoscale_on(False)
chart = config.getboolean("Psychr", "chart")
xlabel = "Tdb, " + Temperature.text()
ylabel = "%s, %s/%s" % (
QtWidgets.QApplication.translate("pychemqt", "Absolute humidity"),
Mass.text(), Mass.text())
tmin = Temperature(config.getfloat("Psychr", "isotdbStart")).config()
tmax = Temperature(config.getfloat("Psychr", "isotdbEnd")).config()
wmin = Temperature(config.getfloat("Psychr", "isowStart")).config()
wmax = Temperature(config.getfloat("Psychr", "isowEnd")).config()
if chart:
self.ax.set_xlabel(xlabel, size="large")
self.ax.set_ylabel(ylabel, size="large")
self.ax.set_xlim(tmin, tmax)
self.ax.set_ylim(wmin, wmax)
self.ax.yaxis.set_ticks_position("right")
self.ax.yaxis.set_label_position("right")
self.ax.figure.subplots_adjust(left=0.05, top=0.95)
else:
self.ax.set_xlabel(ylabel, size="large")
self.ax.set_ylabel(xlabel, size="large")
self.ax.set_xlim(wmin, wmax)
self.ax.set_ylim(tmin, tmax)
self.ax.xaxis.set_ticks_position("top")
self.ax.xaxis.set_label_position("top")
self.ax.figure.subplots_adjust(right=0.95, bottom=0.05)
kw = formatLine(config, "Psychr", "crux")
self.lx = self.ax.axhline(**kw) # the horiz line
self.ly = self.ax.axvline(**kw) # the vert line
def calculo(self):
self.entrada = self.kwargs["entrada"]
metodo = self.kwargs["metodo"]
self.Pout = Pressure(self.kwargs["Pout"])
razon = self.kwargs["razon"]
self.rendimientoCalculado = Dimensionless(self.kwargs["rendimiento"])
if self.kwargs["etapas"]:
self.etapas = self.kwargs["etapas"]
else:
self.etapas = 1.
self.power = Power(self.kwargs["trabajo"])
def f(Pout, rendimiento):
W_ideal = self.__Wideal(Pout)
power = W_ideal * self.entrada.caudalmasico.gs / rendimiento
return power
if metodo in [0, 3] or (metodo == 5 and self.Pout):
if self.etapas == 1:
razon = self.Pout.atm / self.entrada.P.atm
else:
razon = (self.Pout.atm / self.entrada.P.atm)**(1. /
self.etapas)
elif metodo in [1, 4] or (metodo == 5 and razon):
if self.etapas == 1:
self.Pout = Pressure(self.entrada.P * razon)
else:
self.Pout = Pressure(razon**self.etapas * self.entrada.P)
if metodo in [0, 1]:
Wideal = self.__Wideal(self.Pout.atm)
power = Wideal * self.entrada.caudalmasico.gs / self.rendimientoCalculado
self.power = Power(power * self.etapas)
elif metodo == 2:
funcion = lambda P: f(P, self.rendimientoCalculado) - self.power
self.Pout = Pressure(fsolve(funcion, self.entrada.P + 1))
if self.etapas == 1:
razon = self.Pout / self.entrada.P
else:
razon = (self.Pout / self.entrada.P)**(1. / self.etapas)
elif metodo in [3, 4]:
funcion = lambda rendimiento: f(self.Pout.atm, rendimiento
) - self.power
self.rendimientoCalculado = Dimensionless(fsolve(funcion, 0.5))
elif metodo == 5:
Wideal = self.__Wideal(self.Pout.atm)
caudalmasico = MassFlow(
self.power * self.rendimientoCalculado / Wideal, "gs")
self.Tout = self.__Tout(Wideal)
self.entrada = self.entrada.clone(caudalMasico=caudalmasico)
Wideal = self.__Wideal(self.Pout.atm)
self.Tout = Temperature(self.__Tout(Wideal))
self.salida = [self.entrada.clone(T=self.Tout, P=self.Pout)]
self.razonCalculada = Dimensionless(self.Pout / self.entrada.P)
self.deltaT = DeltaT(self.salida[0].T - self.entrada.T)
self.deltaP = DeltaP(self.salida[0].P - self.entrada.P)
self.cp_cv = self.entrada.Gas.cp_cv
self.Pin = self.entrada.P
self.Tin = self.entrada.T
def _Tbar(Z):
"""
Standard temperature as a function of altitude as explain in [1]_
pag 1.1 Eq 4
Parameters
------------
Z : float
Altitude, [m]
Returns
-------
T : float
Temperature, [K]
Examples
--------
Selected point from Table 1 in [1]_
>>> "%0.1f" % _Tbar(-500).C
'18.2'
>>> "%0.1f" % _Tbar(8000).C
'-37.0'
"""
t = 15-0.0065*Z
return Temperature(t, "C")
def RhoS(self, T):
densidad = 0
for i in range(len(self.ids)):
densidad += self.caudalUnitario[i]/self.caudal * \
self.componente[i].RhoS(T)
self.rho = Density(densidad)
self.T = Temperature(T)
def calculo(self):
tdp, tdb, twb, P, Pvs, Pv, ws, w, HR, v, h = self._lib()
self.tdp = Temperature(tdp)
self.tdb = Temperature(tdb)
self.twb = Temperature(twb)
self.P = Pressure(P)
self.Pvs = Pressure(Pvs)
self.Pv = Pressure(Pv)
self.ws = Dimensionless(ws, txt="kgw/kgda")
self.w = Dimensionless(w, txt="kgw/kgda")
self.HR = Dimensionless(HR, txt="%")
self.mu = Dimensionless(w/ws*100)
self.v = SpecificVolume(v)
self.rho = Density(1/v)
self.h = Enthalpy(h, "kJkg")
self.Xa = 1/(1+self.w/0.62198)
self.Xw = 1-self.Xa
def drawlabel(self, name, t, W, label, unit):
"""
Draw annotation for isolines
name: name of isoline
t: x array of line
W: y array of line
label: text value to draw
unit: text units to draw
"""
if self.Preferences.getboolean("Psychr", name + "label"):
TMIN = self.Preferences.getfloat("Psychr", "isotdbStart")
TMAX = self.Preferences.getfloat("Psychr", "isotdbEnd")
tmin = Temperature(TMIN).config()
tmax = Temperature(TMAX).config()
wmin = self.Preferences.getfloat("Psychr", "isowStart")
wmax = self.Preferences.getfloat("Psychr", "isowEnd")
if self.Preferences.getboolean("Psychr", "chart"):
x = tmax - tmin
y = wmax - wmin
i = 0
for ti, wi in zip(t, W):
if tmin <= ti <= tmax and wmin <= wi <= wmax:
i += 1
else:
x = wmax - wmin
y = tmax - tmin
i = 0
for ti, wi in zip(t, W):
if tmin <= wi <= tmax and wmin <= ti <= wmax:
i += 1
if isinstance(label, float):
label = "%4g" % label
if self.Preferences.getboolean("Psychr", name + "units"):
label += unit
pos = self.Preferences.getfloat("Psychr", name + "position")
p = int(i * pos / 100 - 1)
rot = arctan(
(W[p] - W[p - 1]) / y / (t[p] - t[p - 1]) * x) * 360 / 2 / pi
self.plt.ax.annotate(label, (t[p], W[p]),
rotation=rot,
size="small",
ha="center",
va="center")
def readStatefromJSON(self, state):
"""Load instance parameter from saved file"""
self.Pout = Pressure(state["Pout"])
self.Tout = Temperature(state["Tout"])
self.rendimientoCalculado = Dimensionless(state["rendimientoCalculado"]) # noqa
self.power = Power(state["power"])
self.razonCalculada = Dimensionless(state["razonCalculada"])
self.razon = Dimensionless(state["razon"])
self.deltaT = DeltaT(state["deltaT"])
self.deltaP = DeltaP(state["deltaP"])
self.cp_cv = Dimensionless(state["cp_cv"])
self.Pin = Pressure(state["Pin"])
self.Tin = Temperature(state["Tin"])
self.cp_cv = Dimensionless(state["cp_cv"])
self.statusCoste = state["statusCoste"]
if self.statusCoste:
self.C_adq = Currency(state["C_adq"])
self.C_inst = Currency(state["C_inst"])
self.salida = [None]
def calculo(self):
self.entrada = self.kwargs["entrada"]
self.Pout = Pressure(self.kwargs["Pout"])
self.razon = Dimensionless(self.kwargs["razon"])
self.rendimientoCalculado = Dimensionless(self.kwargs["rendimiento"])
self.power = Power(-abs(self.kwargs["trabajo"]))
def f(Pout, rendimiento):
W_ideal = self.__Wideal(Pout)
power = W_ideal * self.entrada.caudalmasico.gs * rendimiento
return power
self.cp_cv = self.entrada.Gas.cp_cv
if self.kwargs["metodo"] in [0, 3] or \
(self.kwargs["metodo"] == 5 and self.Pout):
self.razon = Dimensionless(self.Pout / self.entrada.P)
elif self.kwargs["metodo"] in [1, 4] or \
(self.kwargs["metodo"] == 5 and self.razon):
self.Pout = Pressure(self.entrada.P * self.razon)
if self.kwargs["metodo"] in [0, 1]:
Wideal = self.__Wideal(self.Pout)
G = self.entrada.caudalmasico.gs
self.power = Power(Wideal * G * self.rendimientoCalculado)
elif self.kwargs["metodo"] == 2:
def function(P):
return f(P, self.rendimientoCalculado) - self.power
self.Pout = Pressure(fsolve(function, self.entrada.P.atm + 1),
"atm")
self.razon = Dimensionless(self.Pout / self.entrada.P)
elif self.kwargs["metodo"] in [3, 4]:
def function(rendimiento):
return f(self.Pout.atm, rendimiento) - self.power
self.rendimientoCalculado = Dimensionless(fsolve(function, 0.5))
elif self.kwargs["metodo"] == 5:
Wideal = self.__Wideal(self.Pout)
G = MassFlow(self.power / self.rendimientoCalculado / Wideal, "gs")
self.Tout = self.__Tout(Wideal)
self.entrada = self.entrada.clone(caudalMasico=G)
Wideal = self.__Wideal(self.Pout)
self.Tout = Temperature(self.__Tout(Wideal))
self.razonCalculada = Dimensionless(self.Pout / self.entrada.P)
self.salida = [self.entrada.clone(T=self.Tout, P=self.Pout)]
self.deltaT = DeltaT(self.salida[0].T - self.entrada.T)
self.deltaP = DeltaP(self.salida[0].P - self.entrada.P)
self.Pin = self.entrada.P
self.Tin = self.entrada.T
def readStatefromJSON(self, solid):
if solid:
self._bool = True
self.status = solid["status"]
self.ids = solid["ids"]
self.componente = [Componente(int(i)) for i in self.ids]
self.caudalUnitario = [MassFlow(q) for q in solid["unitFlow"]]
self.caudal = MassFlow(solid["caudal"])
self.diametros = [Length(d, "m", "ParticleDiameter") for d in solid["diametros"]]
self.fracciones = solid["fracciones"]
self.fracciones_acumuladas = solid["fracciones_acumuladas"]
self.diametro_medio = Length(solid["diametro_medio"])
self.rho = Density(solid["rho"])
self.T = Temperature(solid["T"])
else:
self._bool = False
self.status = False
def regresionCurve(self):
dlg = Plot(accept=True)
x = self.curvaDestilacion.column(0)
T = self.curvaDestilacion.column(1, Temperature)
dlg.addData(x, T, color="black", ls="None", marker="s", mfc="red")
parameters, r2 = curve_Predicted(x, T)
xi = arange(0, 1, 0.01)
Ti = [_Tb_Predicted(parameters, x_i) for x_i in xi]
dlg.addData(xi, Ti, color="black", lw=0.5)
# Add equation formula to plot
txt = r"$\frac{T-T_{o}}{T_{o}}=\left[\frac{A}{B}\ln\left(\frac{1}{1-x}"
txt += r"\right)\right]^{1/B}$"
To = Temperature(parameters[0])
txt2 = "\n\n\n$T_o=%s$" % To.str
txt2 += "\n$A=%0.4f$" % parameters[1]
txt2 += "\n$B=%0.4f$" % parameters[2]
txt2 += "\n$r^2=%0.6f$" % r2
dlg.plot.ax.text(0, T[-1], txt, size="14", va="top", ha="left")
dlg.plot.ax.text(0, T[-1], txt2, size="10", va="top", ha="left")
if dlg.exec_():
self.curveParameters = parameters
self.checkStatusCurve()
def createState(self, x, y):
"""Create psychrometric state from click or mouse position"""
tdb = Temperature(x, "conf")
punto = PsychroState(P=self.inputs.P.value, tdb=tdb, w=y)
return punto
def plot(self):
"""Plot chart"""
self.plt.clearPointData()
self.plt.ax.clear()
chart = self.Preferences.getboolean("Psychr", "chart")
self.plt.config(self.Preferences)
filename = conf_dir+"%s_%i.json" % (
PsychroState().__class__.__name__, self.inputs.P.value)
if os.path.isfile(filename):
with open(filename, "r") as archivo:
data = json.load(archivo)
self.status.setText(QtWidgets.QApplication.translate(
"pychemqt", "Loading cached data..."))
QtWidgets.QApplication.processEvents()
else:
self.progressBar.setVisible(True)
self.status.setText(QtWidgets.QApplication.translate(
"pychemqt", "Calculating data..."))
QtWidgets.QApplication.processEvents()
data = PsychroState.calculatePlot(self)
with open(filename, "w") as file:
json.dump(data, file, indent=4)
self.progressBar.setVisible(False)
self.status.setText(
QtWidgets.QApplication.translate("pychemqt", "Plotting..."))
QtWidgets.QApplication.processEvents()
# Saturation line
t = [Temperature(ti).config() for ti in data["t"]]
Hs = data["Hs"]
format = formatLine(self.Preferences, "Psychr", "saturation")
if chart:
self.plt.plot(t, Hs, **format)
else:
self.plt.plot(Hs, t, **format)
# Iso dew bulb temperaure lines, vertial lines in normal h-Tdb plot,
# vertical in mollier diagram
format = formatLine(self.Preferences, "Psychr", "isotdb")
for i, T in enumerate(t):
if chart:
self.plt.plot([T, T], [0, Hs[i]], **format)
else:
self.plt.plot([0, Hs[i]], [T, T], **format)
# Iso humidity lines, horizontal lines in normal h-Tdb plot, vertical
# in mollier diagram
H = data["H"]
th = data["th"]
tm = Temperature(self.Preferences.getfloat("Psychr", "isotdbEnd"))
format = formatLine(self.Preferences, "Psychr", "isow")
for i, H in enumerate(H):
ts = Temperature(th[i]).config()
if chart:
self.plt.plot([ts, tm.config()], [H, H], **format)
else:
self.plt.plot([H, H], [ts, tm.config()], **format)
# Iso relative humidity lines
format = formatLine(self.Preferences, "Psychr", "isohr")
for Hr, H0 in list(data["Hr"].items()):
if chart:
self.plt.plot(t, H0, **format)
self.drawlabel("isohr", t, H0, Hr, "%")
else:
self.plt.plot(H0, t, **format)
self.drawlabel("isohr", H0, t, Hr, "%")
# Iso wet bulb temperature lines
format = formatLine(self.Preferences, "Psychr", "isotwb")
for T, (H, Tw) in list(data["Twb"].items()):
value = Temperature(T).config()
Tw_conf = [Temperature(Twi).config() for Twi in Tw]
txt = Temperature.text()
if chart:
self.plt.plot(Tw_conf, H, **format)
self.drawlabel("isotwb", Tw_conf, H, value, txt)
else:
self.plt.plot(H, Tw_conf, **format)
self.drawlabel("isotwb", H, Tw_conf, value, txt)
# Isochor lines
format = formatLine(self.Preferences, "Psychr", "isochor")
for v, (Td, H) in list(data["v"].items()):
value = SpecificVolume(v).config()
Td_conf = [Temperature(Tdi).config() for Tdi in Td]
txt = SpecificVolume.text()
if chart:
self.plt.plot(Td_conf, H, **format)
self.drawlabel("isochor", Td_conf, H, value, txt)
else:
self.plt.plot(H, Td_conf, **format)
self.drawlabel("isochor", H, Td_conf, value, txt)
if self.plt.state:
self.plt.createCrux(self.plt.state, chart)
self.plt.draw()
self.status.setText("%s %s" % (
QtWidgets.QApplication.translate("pychemqt", "Using"),
PsychroState().__class__.__name__[3:]))
def calculatePlot(cls, parent):
"""Funtion to calculate point in chart"""
Preferences = ConfigParser()
Preferences.read(conf_dir+"pychemqtrc")
parent.setProgressValue(0)
data = {}
P = parent.inputs.P.value
P_kPa = P/1000
t = cls.LineList("isotdb", Preferences)
# Saturation line
Hs = []
for tdb in t:
Hs.append(HAProps("W", "P", P_kPa, "Tdb", tdb, "RH", 1))
parent.setProgressValue(5*len(Hs)/len(t))
data["t"] = t
data["Hs"] = Hs
# left limit of isow lines
H = cls.LineList("isow", Preferences)
th = []
for w in H:
if w:
tdp = HAProps("Tdp", "P", 101.325, "W", w, "RH", 1)
th.append(Temperature(tdp).config())
else:
tmin = Preferences.getfloat("Psychr", "isotdbStart")
th.append(Temperature(tmin).config())
data["H"] = H
data["th"] = th
# Humidity ratio lines
hr = cls.LineList("isohr", Preferences)
Hr = {}
cont = 0
for i in hr:
Hr[i] = []
for tdb in t:
Hr[i].append(HAProps("W", "P", P_kPa, "Tdb", tdb, "RH", i/100))
cont += 1
parent.progressBar.setValue(5+10*cont/len(hr)/len(Hs))
data["Hr"] = Hr
# Twb
lines = cls.LineList("isotwb", Preferences)
Twb = {}
cont = 0
for T in lines:
ws = HAProps("W", "P", P_kPa, "RH", 1, "Tdb", T)
H = [ws, 0]
_td = HAProps("Tdb", "P", P_kPa, "Twb", T, "RH", 0)
Tw = [Temperature(T).config(), Temperature(_td).config()]
cont += 1
parent.progressBar.setValue(15+75*cont/len(lines))
Twb[T] = (H, Tw)
data["Twb"] = Twb
# v
lines = cls.LineList("isochor", Preferences)
V = {}
# rh = arange(1, -0.05, -0.05)
rh = arange(0.00, 1.05, 0.05)
for cont, v in enumerate(lines):
w = []
Td = []
for r in rh:
try:
w.append(HAProps("W", "P", P_kPa, "RH", r, "V", v))
_td = HAProps("Tdb", "P", P_kPa, "RH", r, "V", v)
Td.append(Temperature(_td).config())
except ValueError:
pass
parent.progressBar.setValue(90+10*cont/len(lines))
V[v] = (Td, w)
data["v"] = V
return data
def calculatePlot(cls, parent):
"""Funtion to calculate point in chart"""
Preferences = ConfigParser()
Preferences.read(conf_dir+"pychemqtrc")
parent.setProgressValue(0)
data = {}
P = parent.inputs.P.value
t = cls.LineList("isotdb", Preferences)
# Saturation line
Hs = []
Pvs = []
for ti in t:
Pv = _Psat(ti)
Pvs.append(Pv)
Hs.append(0.62198*Pv/(P-Pv))
parent.setProgressValue(5*len(Hs)/len(t))
data["t"] = t
data["Hs"] = Hs
# left limit of isow lines
H = cls.LineList("isow", Preferences)
th = []
for w in H:
if w:
Pv = w*P/(0.62198+w)
th.append(Temperature(_tdp(Pv)).config())
else:
tmin = Preferences.getfloat("Psychr", "isotdbStart")
th.append(Temperature(tmin).config())
data["H"] = H
data["th"] = th
# Humidity ratio lines
hr = cls.LineList("isohr", Preferences)
Hr = {}
cont = 0
for i in hr:
Hr[i] = []
for pvs in Pvs:
pv = pvs*i/100
Hr[i].append(0.62198*pv/(P-pv))
cont += 1
parent.setProgressValue(5+10*cont/len(hr)/len(Hs))
data["Hr"] = Hr
# Twb
lines = cls.LineList("isotwb", Preferences)
Twb = {}
cont = 0
for T in lines:
H = concatenate((arange(_W(P, T), 0, -0.001), [0.]))
Tw = []
for h in H:
Tw.append(Temperature(_Tdb(T, h, P)).config())
cont += 1
parent.setProgressValue(15+75*cont/len(lines))
Twb[T] = (H, Tw)
data["Twb"] = Twb
# v
lines = cls.LineList("isochor", Preferences)
V = {}
for cont, v in enumerate(lines):
ts = _Tdb_V(v, P)
T = linspace(ts, v*P/287.055, 50)
Td = [Temperature(ti).config() for ti in T]
_W_V
H = [_W_V(ti, P, v) for ti in T]
parent.setProgressValue(90+10*cont/len(lines))
V[v] = (Td, H)
data["v"] = V
return data
def plot(self):
"""Plot chart"""
self.plt.clearPointData()
self.plt.ax.clear()
chart = self.Preferences.getboolean("Psychr", "chart")
self.plt.config(self.Preferences)
filename = conf_dir+"%s_%i.pkl" % (
PsychroState().__class__.__name__, self.inputs.P.value)
if os.path.isfile(filename):
with open(filename, "rb") as archivo:
data = pickle.load(archivo)
self.status.setText(QtWidgets.QApplication.translate(
"pychemqt", "Loading cached data..."))
QtWidgets.QApplication.processEvents()
else:
self.progressBar.setVisible(True)
self.status.setText(QtWidgets.QApplication.translate(
"pychemqt", "Calculating data..."))
QtWidgets.QApplication.processEvents()
data = PsychroState.calculatePlot(self)
pickle.dump(data, open(filename, "wb"))
self.progressBar.setVisible(False)
self.status.setText(
QtWidgets.QApplication.translate("pychemqt", "Plotting..."))
QtWidgets.QApplication.processEvents()
# Saturation line
t = [Temperature(ti).config() for ti in data["t"]]
Hs = data["Hs"]
format = formatLine(self.Preferences, "Psychr", "saturation")
if chart:
self.plt.plot(t, Hs, **format)
else:
self.plt.plot(Hs, t, **format)
# Iso dew bulb temperaure lines, vertial lines in normal h-Tdb plot,
# vertical in mollier diagram
format = formatLine(self.Preferences, "Psychr", "isotdb")
for i, T in enumerate(t):
if chart:
self.plt.plot([T, T], [0, Hs[i]], **format)
else:
self.plt.plot([0, Hs[i]], [T, T], **format)
# Iso humidity lines, horizontal lines in normal h-Tdb plot, vertical
# in mollier diagram
H = data["H"]
th = data["th"]
tm = Temperature(self.Preferences.getfloat("Psychr", "isotdbEnd"))
format = formatLine(self.Preferences, "Psychr", "isow")
for i, H in enumerate(H):
if chart:
self.plt.plot([th[i], tm.config()], [H, H], **format)
else:
self.plt.plot([H, H], [th[i], tm.config()], **format)
# Iso relative humidity lines
format = formatLine(self.Preferences, "Psychr", "isohr")
for Hr, H0 in list(data["Hr"].items()):
if chart:
self.plt.plot(t, H0, **format)
self.drawlabel("isohr", t, H0, Hr, "%")
else:
self.plt.plot(H0, t, **format)
self.drawlabel("isohr", H0, t, Hr, "%")
# Iso wet bulb temperature lines
format = formatLine(self.Preferences, "Psychr", "isotwb")
for T, (H, Tw) in list(data["Twb"].items()):
value = Temperature(T).config()
txt = Temperature.text()
if chart:
self.plt.plot(Tw, H, **format)
self.drawlabel("isotwb", Tw, H, value, txt)
else:
self.plt.plot(H, Tw, **format)
self.drawlabel("isotwb", H, Tw, value, txt)
# Isochor lines
format = formatLine(self.Preferences, "Psychr", "isochor")
for v, (Td, H) in list(data["v"].items()):
value = SpecificVolume(v).config()
txt = SpecificVolume.text()
if chart:
self.plt.plot(Td, H, **format)
self.drawlabel("isochor", Td, H, value, txt)
else:
self.plt.plot(H, Td, **format)
self.drawlabel("isochor", H, Td, value, txt)
if self.plt.state:
self.plt.createCrux(self.plt.state, chart)
self.plt.draw()
self.status.setText("%s %s" % (
QtWidgets.QApplication.translate("pychemqt", "Using"),
PsychroState().__class__.__name__[3:]))
def __init__(self, parent=None):
super(Definicion_Petro, self).__init__(parent)
self.setWindowTitle(QtGui.QApplication.translate(
"pychemqt", "Petrol component definition"))
layout = QtGui.QGridLayout(self)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Name")), 1, 1)
self.nombre = QtGui.QLineEdit()
self.nombre.textChanged.connect(partial(self.changeParams, "name"))
layout.addWidget(self.nombre, 1, 2, 1, 4)
layout.addItem(QtGui.QSpacerItem(10, 10, QtGui.QSizePolicy.Fixed,
QtGui.QSizePolicy.Fixed), 2, 1, 1, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Boiling point")), 3, 1)
self.Tb = Entrada_con_unidades(Temperature)
self.Tb.valueChanged.connect(partial(self.changeParams, "Tb"))
layout.addWidget(self.Tb, 3, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Molecular Weight")), 4, 1)
self.M = Entrada_con_unidades(float, textounidad="g/mol")
self.M.valueChanged.connect(partial(self.changeParams, "M"))
layout.addWidget(self.M, 4, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Specific Gravity")), 5, 1)
self.SG = Entrada_con_unidades(float)
self.SG.valueChanged.connect(partial(self.changeParams, "SG"))
layout.addWidget(self.SG, 5, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "API gravity")), 6, 1)
self.API = Entrada_con_unidades(float)
self.API.valueChanged.connect(partial(self.changeParams, "API"))
layout.addWidget(self.API, 6, 2)
layout.addWidget(QtGui.QLabel("K watson:"), 7, 1)
self.Kw = Entrada_con_unidades(float)
self.Kw.valueChanged.connect(partial(self.changeParams, "Kw"))
layout.addWidget(self.Kw, 7, 2)
layout.addWidget(QtGui.QLabel("C/H:"), 8, 1)
self.CH = Entrada_con_unidades(float)
self.CH.valueChanged.connect(partial(self.changeParams, "CH"))
layout.addWidget(self.CH, 8, 2)
layout.addWidget(QtGui.QLabel(u"ν<sub>100F</sub>:"), 9, 1)
self.v100 = Entrada_con_unidades(Diffusivity)
self.v100.valueChanged.connect(partial(self.changeParams, "v100"))
layout.addWidget(self.v100, 9, 2)
layout.addWidget(QtGui.QLabel(u"ν<sub>210F</sub>:"), 10, 1)
self.v210 = Entrada_con_unidades(Diffusivity)
self.v210.valueChanged.connect(partial(self.changeParams, "v210"))
layout.addWidget(self.v210, 10, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Refraction index")), 11, 1)
self.n = Entrada_con_unidades(float)
self.n.valueChanged.connect(partial(self.changeParams, "n"))
layout.addWidget(self.n, 11, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Huang parameter")), 12, 1)
self.I = Entrada_con_unidades(float)
self.I.valueChanged.connect(partial(self.changeParams, "I"))
layout.addWidget(self.I, 12, 2)
layout.addWidget(QtGui.QLabel("%S"), 13, 1)
self.S = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.S.valueChanged.connect(partial(self.changeParams, "S"))
layout.addWidget(self.S, 13, 2)
layout.addWidget(QtGui.QLabel("%H"), 14, 1)
self.H = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.H.valueChanged.connect(partial(self.changeParams, "H"))
layout.addWidget(self.H, 14, 2)
layout.addWidget(QtGui.QLabel("%N"), 15, 1)
self.N = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.N.valueChanged.connect(partial(self.changeParams, "N"))
layout.addWidget(self.N, 15, 2)
layout.addWidget(QtGui.QLabel(QtGui.QApplication.translate(
"pychemqt", "Carbons number")), 19, 1)
self.carbonos = Entrada_con_unidades(int, width=50, spinbox=True,
step=1, start=7, min=5, max=100)
self.N.valueChanged.connect(partial(self.changeParams, "Nc"))
layout.addWidget(self.carbonos, 19, 2)
layout.addItem(QtGui.QSpacerItem(10, 10, QtGui.QSizePolicy.Expanding,
QtGui.QSizePolicy.Expanding), 3, 3, 15, 1)
self.checkCurva = QtGui.QCheckBox(QtGui.QApplication.translate(
"pychemqt", "Define destillation curve"))
layout.addWidget(self.checkCurva, 3, 4, 1, 2)
self.tipoCurva = QtGui.QComboBox()
self.tipoCurva.addItem("ASTM D86")
self.tipoCurva.addItem("TBP")
self.tipoCurva.addItem("EFV")
self.tipoCurva.addItem("ASTM D1186")
self.tipoCurva.addItem("ASTM D2887 (SD)")
self.tipoCurva.setEnabled(False)
layout.addWidget(self.tipoCurva, 4, 4, 1, 2)
self.textoPresion = QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Pressure"))
self.textoPresion.setEnabled(False)
layout.addWidget(self.textoPresion, 5, 4)
self.presion = Entrada_con_unidades(Pressure, value=101325.)
self.presion.setEnabled(False)
self.presion.valueChanged.connect(partial(self.changeParams, "P_dist"))
layout.addWidget(self.presion, 5, 5)
self.curvaDestilacion = Tabla(
2, filas=1, horizontalHeader=["%dist", "Tb, "+Temperature.text()],
verticalHeader=False, dinamica=True)
self.curvaDestilacion.setEnabled(False)
self.curvaDestilacion.editingFinished.connect(self.changeCurva)
layout.addWidget(self.curvaDestilacion, 6, 4, 13, 2)
self.checkBlend = QtGui.QCheckBox(QtGui.QApplication.translate(
"pychemqt", "Blend if its necessary"))
layout.addWidget(self.checkBlend, 19, 4, 1, 2)
self.checkCurva.toggled.connect(self.tipoCurva.setEnabled)
self.checkCurva.toggled.connect(self.presion.setEnabled)
self.checkCurva.toggled.connect(self.textoPresion.setEnabled)
self.checkCurva.toggled.connect(self.curvaDestilacion.setEnabled)
layout.addItem(QtGui.QSpacerItem(20, 20, QtGui.QSizePolicy.Fixed,
QtGui.QSizePolicy.Fixed), 20, 1, 1, 2)
self.checkCrudo = QtGui.QCheckBox(QtGui.QApplication.translate(
"pychemqt", "Use petrol fraction from list"))
self.checkCrudo.toggled.connect(self.changeUnknown)
layout.addWidget(self.checkCrudo, 21, 1, 1, 2)
self.crudo = QtGui.QComboBox()
self.crudo.setEnabled(False)
self.crudo.addItem("")
for i in crudo[1:]:
self.crudo.addItem("%s (%s) API: %s %S: %s" % (i[0], i[1], i[3], i[4]))
# i[0]+" ("+i[1]+")"+" API: "+str(i[3])+" %S: "+str(i[4]))
self.crudo.currentIndexChanged.connect(partial(
self.changeParams, "indice"))
layout.addWidget(self.crudo, 23, 1, 1, 5)
layout.addWidget(QtGui.QLabel("Pseudo C+"), 24, 1)
self.Cplus = Entrada_con_unidades(int, width=50, spinbox=True, step=1,
min=6)
self.Cplus.valueChanged.connect(partial(self.changeParams, "Cplus"))
layout.addWidget(self.Cplus, 24, 2)
self.checkCrudo.toggled.connect(self.crudo.setEnabled)
self.checkCrudo.toggled.connect(self.Cplus.setEnabled)
layout.addItem(QtGui.QSpacerItem(5, 5, QtGui.QSizePolicy.Expanding,
QtGui.QSizePolicy.Expanding), 29, 1, 1, 2)
newComponent.loadUI(self)
self.Petroleo = Petroleo()
self.Crudo = Crudo()
def __init__(self, parent=None):
super(Definicion_Petro, self).__init__(parent)
self.setWindowTitle(
QtGui.QApplication.translate("pychemqt",
"Petrol component definition"))
layout = QtGui.QGridLayout(self)
layout.addWidget(
QtGui.QLabel(QtGui.QApplication.translate("pychemqt", "Name")), 1,
1)
self.nombre = QtGui.QLineEdit()
self.nombre.textChanged.connect(partial(self.changeParams, "name"))
layout.addWidget(self.nombre, 1, 2, 1, 4)
layout.addItem(
QtGui.QSpacerItem(10, 10, QtGui.QSizePolicy.Fixed,
QtGui.QSizePolicy.Fixed), 2, 1, 1, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Boiling point")), 3,
1)
self.Tb = Entrada_con_unidades(Temperature)
self.Tb.valueChanged.connect(partial(self.changeParams, "Tb"))
layout.addWidget(self.Tb, 3, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Molecular Weight")),
4, 1)
self.M = Entrada_con_unidades(float, textounidad="g/mol")
self.M.valueChanged.connect(partial(self.changeParams, "M"))
layout.addWidget(self.M, 4, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Specific Gravity")),
5, 1)
self.SG = Entrada_con_unidades(float)
self.SG.valueChanged.connect(partial(self.changeParams, "SG"))
layout.addWidget(self.SG, 5, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "API gravity")), 6, 1)
self.API = Entrada_con_unidades(float)
self.API.valueChanged.connect(partial(self.changeParams, "API"))
layout.addWidget(self.API, 6, 2)
layout.addWidget(QtGui.QLabel("K watson:"), 7, 1)
self.Kw = Entrada_con_unidades(float)
self.Kw.valueChanged.connect(partial(self.changeParams, "Kw"))
layout.addWidget(self.Kw, 7, 2)
layout.addWidget(QtGui.QLabel("C/H:"), 8, 1)
self.CH = Entrada_con_unidades(float)
self.CH.valueChanged.connect(partial(self.changeParams, "CH"))
layout.addWidget(self.CH, 8, 2)
layout.addWidget(QtGui.QLabel(u"ν<sub>100F</sub>:"), 9, 1)
self.v100 = Entrada_con_unidades(Diffusivity)
self.v100.valueChanged.connect(partial(self.changeParams, "v100"))
layout.addWidget(self.v100, 9, 2)
layout.addWidget(QtGui.QLabel(u"ν<sub>210F</sub>:"), 10, 1)
self.v210 = Entrada_con_unidades(Diffusivity)
self.v210.valueChanged.connect(partial(self.changeParams, "v210"))
layout.addWidget(self.v210, 10, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Refraction index")),
11, 1)
self.n = Entrada_con_unidades(float)
self.n.valueChanged.connect(partial(self.changeParams, "n"))
layout.addWidget(self.n, 11, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Huang parameter")),
12, 1)
self.I = Entrada_con_unidades(float)
self.I.valueChanged.connect(partial(self.changeParams, "I"))
layout.addWidget(self.I, 12, 2)
layout.addWidget(QtGui.QLabel("%S"), 13, 1)
self.S = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.S.valueChanged.connect(partial(self.changeParams, "S"))
layout.addWidget(self.S, 13, 2)
layout.addWidget(QtGui.QLabel("%H"), 14, 1)
self.H = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.H.valueChanged.connect(partial(self.changeParams, "H"))
layout.addWidget(self.H, 14, 2)
layout.addWidget(QtGui.QLabel("%N"), 15, 1)
self.N = Entrada_con_unidades(float, spinbox=True, step=1.0, max=100)
self.N.valueChanged.connect(partial(self.changeParams, "N"))
layout.addWidget(self.N, 15, 2)
layout.addWidget(
QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Carbons number")),
19, 1)
self.carbonos = Entrada_con_unidades(int,
width=50,
spinbox=True,
step=1,
start=7,
min=5,
max=100)
self.N.valueChanged.connect(partial(self.changeParams, "Nc"))
layout.addWidget(self.carbonos, 19, 2)
layout.addItem(
QtGui.QSpacerItem(10, 10, QtGui.QSizePolicy.Expanding,
QtGui.QSizePolicy.Expanding), 3, 3, 15, 1)
self.checkCurva = QtGui.QCheckBox(
QtGui.QApplication.translate("pychemqt",
"Define destillation curve"))
layout.addWidget(self.checkCurva, 3, 4, 1, 2)
self.tipoCurva = QtGui.QComboBox()
self.tipoCurva.addItem("ASTM D86")
self.tipoCurva.addItem("TBP")
self.tipoCurva.addItem("EFV")
self.tipoCurva.addItem("ASTM D1186")
self.tipoCurva.addItem("ASTM D2887 (SD)")
self.tipoCurva.setEnabled(False)
layout.addWidget(self.tipoCurva, 4, 4, 1, 2)
self.textoPresion = QtGui.QLabel(
QtGui.QApplication.translate("pychemqt", "Pressure"))
self.textoPresion.setEnabled(False)
layout.addWidget(self.textoPresion, 5, 4)
self.presion = Entrada_con_unidades(Pressure, value=101325.)
self.presion.setEnabled(False)
self.presion.valueChanged.connect(partial(self.changeParams, "P_dist"))
layout.addWidget(self.presion, 5, 5)
self.curvaDestilacion = Tabla(
2,
filas=1,
horizontalHeader=["%dist", "Tb, " + Temperature.text()],
verticalHeader=False,
dinamica=True)
self.curvaDestilacion.setEnabled(False)
self.curvaDestilacion.editingFinished.connect(self.changeCurva)
layout.addWidget(self.curvaDestilacion, 6, 4, 13, 2)
self.checkBlend = QtGui.QCheckBox(
QtGui.QApplication.translate("pychemqt", "Blend if its necessary"))
layout.addWidget(self.checkBlend, 19, 4, 1, 2)
self.checkCurva.toggled.connect(self.tipoCurva.setEnabled)
self.checkCurva.toggled.connect(self.presion.setEnabled)
self.checkCurva.toggled.connect(self.textoPresion.setEnabled)
self.checkCurva.toggled.connect(self.curvaDestilacion.setEnabled)
layout.addItem(
QtGui.QSpacerItem(20, 20, QtGui.QSizePolicy.Fixed,
QtGui.QSizePolicy.Fixed), 20, 1, 1, 2)
self.checkCrudo = QtGui.QCheckBox(
QtGui.QApplication.translate("pychemqt",
"Use petrol fraction from list"))
self.checkCrudo.toggled.connect(self.changeUnknown)
layout.addWidget(self.checkCrudo, 21, 1, 1, 2)
self.crudo = QtGui.QComboBox()
self.crudo.setEnabled(False)
self.crudo.addItem("")
for i in crudo[1:]:
self.crudo.addItem("%s (%s) API: %s %S: %s" %
(i[0], i[1], i[3], i[4]))
# i[0]+" ("+i[1]+")"+" API: "+str(i[3])+" %S: "+str(i[4]))
self.crudo.currentIndexChanged.connect(
partial(self.changeParams, "indice"))
layout.addWidget(self.crudo, 23, 1, 1, 5)
layout.addWidget(QtGui.QLabel("Pseudo C+"), 24, 1)
self.Cplus = Entrada_con_unidades(int,
width=50,
spinbox=True,
step=1,
min=6)
self.Cplus.valueChanged.connect(partial(self.changeParams, "Cplus"))
layout.addWidget(self.Cplus, 24, 2)
self.checkCrudo.toggled.connect(self.crudo.setEnabled)
self.checkCrudo.toggled.connect(self.Cplus.setEnabled)
layout.addItem(
QtGui.QSpacerItem(5, 5, QtGui.QSizePolicy.Expanding,
QtGui.QSizePolicy.Expanding), 29, 1, 1, 2)
newComponent.loadUI(self)
self.Petroleo = Petroleo()
self.Crudo = Crudo()
